Utilization of Waste Tires in the Production of Non-Structural Portland... Concrete By Prof. Osama A. Abaza

Utilization of Waste Tires in the Production of Non-Structural Portland Cement
Concrete
By
Prof. Osama A. Abaza
Abstract
This paper aims to explore the potential utilization of waste crumb tires in various Portland
Cement Concrete categories for the production of non-structural Portland cement concrete.
Fine aggregate (sand) was replaced using volumetric method by waste crumb tires with 0, 25,
50, 75, and 100% replacements for the various PCC categories of B-150, 200, 250, 300, and
B-450 kg/cm2.
Physical characteristics on fresh and hardened concrete were studied by various tests.
Concrete mixes which contained waste crumb were compared with those that had 0%
replacement.
Compressive strength, density, and modulus of elasticity decreased as the percent replacement
by waste crumb tires increased; water absorption initially decreased and started to increase
after an increasing in the percent of replacement, slump showed no significant change.
Abrasion resistance, noise and thermal insulation increased as the percent replacement
increased.
Finally it is recommended to use waste crumb tires for non-structural Portland cement
concrete, such as floor rips, partitions, back stone concrete, concrete blocks, and other nonstructural uses.
1. Introduction
The waste problem considered as one of the most crucial problems facing the world as a
source of the environmental pollution.
During last recent years, many improvements in West Bank have occurred in all parts of life
such as social, industrial, economical etc. Like all countries in the world, this will lead to
generate new ways of living and increase the human requirements, and will also increase
types and quantities of the waste in the West Bank, without any active processes to provide
solution to this problem.
Waste rubber tires cause serious environmental problems all over the world. One of the
potential means of utilizing the waste tires is to process this waste material for the protection
of the environment and society. It is suggested to use this waste tires as an additive in
Portland cement concrete (PCC) mixes for non-structural applications, which would partially
help in solving this problem.
The objective of this paper is to investigate the utilization of rubber tires in the form of
shredded tires (crumbs) in PCC for non-structural concrete through investigating its impact on
the physical characteristics of PCC as compressive strength, workability, water absorption
(porosity), noise insulation, thermal insulation, and abrasion.
Disposal of tires has become one of the serious problems for the environment. Land-filling is
becoming unacceptable for waste tires because of the rapid depletion of available sites for
waste disposal.
2. Background
The use of rubber waste shredded tires was studied in the past by many researchers.
A systematic experimental study was performed recently for improving strength and
toughness of Rubber Modified Concrete (RMC) (Xi et al. 2003).
In the study of the development of waste tire modified concrete, two types of waste tire
configurations were evaluated (Guoqiang et al. 2004). One was in the form of chips, or
particles and the other was in the form of fibers.
Another research was done using Chopped Worn-Out Tires in production of light weight
concrete masonry units (Al-Hadithi et al. 1999).
Raghvan et al. (1998) reported that mortars incorporating rubber shreds achieved workability
(defined as the ease with which mortar/concrete can be mixed, transported and placed)
comparable to or better than a control mortar without rubber particles.
Khatib and Bayomy (1999) investigated the workability of rubber concrete and reported that
there was a decrease in slump with increase in rubber content as a percentage of total
aggregate volume.
Another research was done using Chopped Worn-Out Tires in production of light weight
concrete masonry units (Al-Hadithi et al. 1999). This research, generally aimed at defining the
possibility of using chopped worn-out tires to produce lightweight concrete building units.
3. Work Procedure
The basic ingredients of PCC and its products, which were used in this research work were
normal Portland cement (Cement type 1), Natural Coarse aggregate (sedimentary rock
source), Natural Fine aggregate (sand), Water (fresh drinkable water), and Grinded tires (fine
crumb tires).
3.1 Raw Material Tests
The raw materials used in this research work were tested for the purpose of identification of
basic physical characteristics using the following tests:
-
Sieve analysis. (ASTM C-136)
Specific gravity and water absorption. (ASTM C-127)
Abrasion (Lose Angles abrasion test). (ASTM C-88)
Amount of fines and injurious particles (Sand equivalent) (ASTM D-2419).
3.2 Plain Portland Cement Concrete Mixes
Standard Portland cement concrete mixes without crumb rubber were made with different
grades and different water cement ratios. These mixes were used as a reference standard
comparison mixes. Such mixes reflect the local design mixes used by the ready mix plants.
Table 1 shows the mix ingredients for a batch of 0.01 cubic meters.
Table (1): Mix ingredients (kg/0.01m3 of PCC)
Concrete Grade
Coarse aggregate
Fine aggregate (sand)
Cement
Water
W/C
B-150
12.95
5.0
2.0
1.9
0.95
B-200
12.95
5.2
2.2
1.95
0.89
B-250
12.50
5.8
2.6
1.9
0.73
B-300
12.50
5.8
2.9
1.8
0.62
B-450
12.50
5.5
4.7
2.0
0.43
3.3 Crumb Portland Cement Concrete Mixes
Portland cement concrete mixes utilizing crumb waste tires by volumetric replacement of
sand with different proportions of replacements, basically 25, 50, 75, and 100% replacements
were made. Table 2 shows the replacement of fine aggregate (sand) in different proportions
by the crumb waste tires volumetric for B-150 grade as an example.
By dividing the weight of sand to be replaced by crumb waste tires by its specific gravity, the
volume of sand was obtained; this volume is to be replaced by volume of crumb tire waste
converted to weight using the following physical characteristics which was tested as a part of
this thesis:
Table (2): Grade B-150 of PCC for batch mix
B-150
0.0% of sand by weight is to be replaced by shredded tires
Weight of sand (gm)
Volume of sand (cm3)
Equivalent Weight of shredded tires (Kg)
5000
1893.9
0.0
Weight of sand (gm)
1250
Weight of sand (gm)
2500
Weight of sand (gm)
3750
Weight of sand (gm)
5000
25% of sand by weight is to be replaced by shredded tires
Volume of sand (cm3)
Equivalent Weight of shredded tires (Kg)
473.5
0.540
50% of sand by weight is to be replaced by shredded tires
Volume of sand (cm3)
Equivalent Weight of shredded tires (Kg)
947.0
1.080
75% of sand by weight is to be replaced by shredded tires
Volume of sand (cm3)
Equivalent Weight of shredded tires (Kg)
1420.5
1.619
100% of sand by weight is to be replaced by shredded tires
Volume of sand (cm3)
Equivalent Weight of shredded tires (Kg)
1893.9
2.159
3.4 Tests on PCC
Slump test was made on fresh concrete to measure the effect of change in ingredients on
workability according to the addition of crumb waste tires.
The following tests on hardened concrete were made using four specimens (cubes) from each
proportion made:
- Compressive Strength (PS-55): It is worth to note that the Palestinian standard requires a 7
days curing while the ASTM standards require a curing conditions 28 days curing after
casting the molds.
- Water Absorption (ASTM C-642).
- Abrasion (ASTM C-944).
- Modulus of Elasticity (ASTM C-469).
- Weight before replacement and weight after replacement.
3.4 Thermal and Sound Insulation testing
For sound and thermal insulation, a concrete wood mold having a dimension of 15x15x5cm
was made, three specimens of each proportion were made with 0.0%, 25%, 50%, 75% and
100% crumbed waste tires with properties same as that of concrete cubes mixes.
A wooden box was made in a way that the heat will be directly move or transfer from one
chamber having constant temperature exposed on one of the faces of the specimen for a
period of time through the specimen to another chamber. The temperature was measured until
the temperature became constant in the two faces of concrete specimen using a laser
thermometer (High Temperature Infrared Thermometer, Type K/J/T/E/R). Figures 3.2, 3.3,
and 3.4 show the mechanism of the testing.
Figure 3.2: Wooden box face with two opening one for source and the other for
measuring (40x40x100cm Dimension)
Figure 3.3: Wooden box back (the other face) with one opening for measuring.
Figure 3.4: Specimen location (at the middle of the wooden box) with frame dimension
15x15x15 cm
The same procedure was made for testing the sound insulation using a constant noise source
and a noise measuring device (Sound Level Meter Auto range, RS – 232).
4. Experimental Results and discussion
4.1 Materials Testing Results
The physical characteristics of the materials which were obtained from tests results mentioned
that were made on lab:
-
Dry Rodded Weight of Sand = 1.431 g/cm3
Dry Rodded Weight of crumbed tires waste = 0.640 g/cm3
Specific Gravity of Sand = 2.644 g/cm3
Specific Gravity of crumbed waste tires = 1.140 g/cm3
Table 3 summarizes the tests results of the properties of materials used in this research. Notice
that these materials are used locally in West Bank by concrete plants, and Figure 1 gives the
specification of aggregates used in the mixes.
Table (3): Materials tests results
RESULTS OF AGGREGATE TESTING
1- Gradation (AASHTO T-27)
Sieve No.
Coarse agg.
Fine agg.
Shredded tires, (crumb)
1"
100
-
3/4"
75
-
1/2"
59
100
-
3/8"
54
100
-
#4
26
99.0
-
#8
11
97.0
-
# 16
3.9
92.2
-
# 30
3.3
64.6
100
# 50
2.8
26.3
47.4
# 100
2.5
6.1
26.7
# 200
2.4
3.9
0.0
Result
No.
Type of test
Standard
2.
Bulk specific gravity
3.
Sp.Gr. (Saturated surface Dry – SSD)
Unit
Coarse agg.
Fine agg.
Shredded tires
-
2.560
2.521
1.131
-
2.621
2.640
1.140
ASTM C-127
4.
Sp.Gr. (Apparent)
-
2.716
2.734
1.152
5.
Water absorption
%
1.02
0.5
-
6.
Los Angeles abrasion
7.
Sand equivalent
8.
Clay lumps and friable particles
Percent Passing (%)
100
90
80
70
60
50
40
30
20
10
0
0.01
ASTM C-88
%
30.1
-
-
ASTM D-2419
-
-
66.0
-
ASTM-C142
%
1.1
-
-
10
100
crumb waste tires
fine agregate (sand)
Coarse aggregate
0.1
1
Sieve size (mm)
Figure 1: Particle size distribution
4.2 Compressive Strength
As a result of a volumetric replacement of sand by crumb waste tires, compressive strength
decreases as percent of crumb waste tires increases as shown in Figure 2.
Figure 2 shows how compressive strength changed with percent of volumetric replacement of
sand by waste crumb tires relative to the specified compressive strength.
Notice actual compressive strength at 0, 25, 50, 75, and 100% replacement for grades B-150,
200, 250, 300, and B-450, actual compressive strength differences are less decreased at
concrete grades B-150 and B-200 versus replacement, differences of compressive strength
increases at concrete grades B-250, 300, and B-450 versus replacement.
Actual
compressive
strength (kg/cm2)
As an example; for concrete grade of B-450 the differences between compressive strengths
are 39.7, 20.0, 36.5, and 36.0%, while for concrete grade of B-200 the differences are 13.1,
28.1, 30.1, and 21.8%.
500
450
400
350
300
250
200
150
100
50
0
0% Replacement
50% Replacement
100% Replacement
150
200
25% Replacement
75% Replacement
250
300
350
400
450
Specified compressive strength (kg/cm2)
Figure 2: Compressive strength of Portland cement
concrete for various percentages of replacements of
crumbed waste tires
Figure 2 shows how actual compressive strength decreased at specified compressive strength
with increasing percent of replacement of waste crumb tires. This happened because as
replacement increases, bonding between aggregate particles and cement decrease, and
because of the weakness of waste crumb rubber particles with comparison to sand.
4.3 Density
Density of concrete also decreases as crumb waste tires increases, see Figure 3 which presents
how density decreases when crumb waste tire increases.
Density kg/m3
2500
PCC 150
PCC 200
PCC 250
PCC 300
PCC 450
2400
2300
2200
2100
2000
1900
0
20
40
60
Percent replacement
Figure 3: Perecent replacement by crumb waste tire
versus density for various categories of concrete
80
100
Theses differences show slight differences in densities between different PCC categories
versus replacement, but the decreases for each type on density reaches between (16-19%) at
100% replacement.
Generally, density decreases as percent replacement increases since waste crumb rubber has
lower specific gravity than sand.
4.4 Water Absorption
Water absorption decreases at 25% replacement and pounces back approximately to its
original value at 50% replacement and starts to increase as waste crumb tires increases (see
Figure 4 for PCC-150).
Water Absorption
(%)
9
PCC 150
PCC 200
PCC 250
PCC 300
PCC 450
8
7
6
5
0
20
40
60
80
Percent replacement
Figure 4: Perecent replacement by crumb waste tire
versus Water Absorption for various categories of concrete
100
This leads to the idea that water absorption decreased at 25% replacement since voids are
decreased but occasional vacuums existed when waste crumb tires replacement increased
which causes an increase in water absorption. In addition, weakness of bonding between
particles will increase absorption which permits water to enter through voids in the interface
between the crumbs and the cement paste as a result of increasing waste crumb tires. It is
worth to note that the waste crumb tires have smaller particle size compared to that of sand as
seen in Figure 1.
4.5 Slump (Consistency)
Slump is an expression of consistency, as slump increases the concrete blend is more
consistent. Figure 5 shows slump versus replacement for different PCC categories.
Slump (mm)
35
30
25
20
B-150
B-200
B-250
15
B-300
B-450
10
0
20
40
60
Percent replacement
Figure 5: Percent replacement by crumb waste tires
versus slump for various PCC categories
80
100
Slump showed little change in consistency during all mixing; slump ranges from 20-30 mm,
there was no effect of increasing waste crumb tires replacement on consistency. This is
because of the coarseness of the mixes and the existence of high adhesion forces between
waste crumb particles and aggregate particles which prevents mixes to be more consistent.
4.6 Abrasion
Figure 6 represents abrasion test results for concrete versus percent replacement for.
12
B-150
B-200
B-250
B-300
B-450
Abrasion (gm)
10
8
6
4
2
0
0
20
40
60
80
Percent replacement
Figure 6: Percent replacement by crumb waste tires versus
abrasion for various PCC categories
100
It is noticed that abrasion increases when replacement increases, this is because of the
increase of waste crumb tires replacement. This happened because of the existing of fine
crumb waste tires which has a weak resistance and of the weakness of bonding between the
blend particles due to increasing of waste crumb tires percent replacement. On the other hand
sand has a coarse surface texture and because of the nature micro structures of sand (silica
quarts) that made bonding stronger with comparison to rubber.
4.7 Modulus of Elasticity
Elasticity (KN/mm)
Figure 7 shows modulus of elasticity versus replacement of waste crumb tires for different
categories of PCC.
400
350
300
250
200
150
100
50
0
B-150
B-200
B-250
B-300
B-450
0
20
40
60
80
Percent replacement
Figure 7: Percent replacement by crumb waste
tires versus elasticity for various PCC categories
Modulus of elasticity decreased as waste crumb tires replacement increased.
100
4.8 Noise Insulation
Figure 8 shows results of noise insulation at low level of noise (86.5 dp), this Figure presents
percent replacement of waste crumb tires versus percent reduction of noise at low level for
various PCC categories.
% Reduction
19
18
17
16
15
14
150 low
200 low
250 low
300 low
450 low
Average Low
13
0
20
40
60
80
Replacement
Figure 8: Percent replacement of waste crumb tires versus
reduction of noise at low level for various PCC categories
100
Figure 8 shows obviously the behavior of noise, as replacement increased, higher reduction of
noise, this means that when replacement increased insulation increased.
From the above Figure the reduction increased from 14% at 0% replacement to approximately
19% at 100% replacement.
Figure 9 also presents percent replacement of waste crumb tires versus percent reduction of
noise at high noise level (98.6 dp) for various PCC categories.
% Reduction
19
18
17
150 high
200 high
250 high
300 high
450 high
Average High
16
15
14
13
0
20
40
60
Replacement
Figure 9: Percent replacement of waste crumb tires
versus noise reduction at high level for various PCC
80
100
The above Figure shows the same behavior as low noise level but with less noise reduction or
less insulation. Reduction of noise increased from 13.5% approximately at 0.0% replacement
to 18% at 100% replacement.
Figure 10 shows percent replacement versus averages of noise reduction at low and high
levels.
19
% Reduction
18
17
16
15
14
Average High
Average Low
13
0
20
40
60
Replacement
Figure 10: Percent replacement of waste crumb tires
versus average reduction of noise at low and high level
80
100
At low noise level higher insulation of noise occurred than high level of noise which easily
noticed from Figure 5.16.
The difference between reduction of noise at low level and high level, at 0, 25, 50, 75, and
100% is 0.74, 1.16, 1.66, 1.66, and 0.78 respectively, that gives higher increasing at low level
of 5.5, 8.3, 11.4, 10.6, and 4.4% than the high noise level with an overall average of 8.0%.
The more the material is brittle it will have lower noise insulation; the more the material is
elastic it will have higher noise insulation. This means that when percent replacement
increased concrete absorption of noise increased.
Concrete with different percent replacement can isolate noise at low level better than high
noise level, since concrete can absorb vibration at low level better than high level.
4.9 Thermal Insulation
Figure 11 shows results of thermal insulation at a constant source of heat (54 C°), this Figure
presents percent replacement of waste crumb tires versus percent reduction of temperature for
various PCC categories.
Figure 11 shows that percent reduction in temperature increased as waste crumb tires
replacement increased, that leads the fact that thermal insulation increased as the percent
replacement increased. No significant changes can be noticed between various PCC
categories.
% Reduction
34
150
200
250
300
450
Average
32
30
28
26
24
22
0
20
40
60
80
Replacement
Figure 11: Percent replacement of waste crumb tires
versus temperature reduction for various PCC categories
100
Figure 12 shows the average percent reduction of temperature versus percent replacement of
waste crumb tires for all PCC categories.
Average reduction increased as percent replacement increased, at 0, 25, 50, 75, and 100%
replacement percent reduction is 23.5, 24.4, 26.7, 29.0, and 30.9% respectively, which means
that thermal insulation increased 3.8, 13.6, 23.4, and 31.5% from zero percent replacement.
% Reduction
34
Average
32
30
28
26
24
22
0
20
40
60
Replacement
Figure 12: Percent replacement of waste crumb tires
versus average temperature reduction for various PCC
80
100
This behavior happened because when the material density is lowered thermal insulation
increased, and because of lower conductivity that rubber has with comparison of concrete.
5. Conclusions and Recommendations
6.1 Conclusions
Based on the results and analysis done as a part of this research, the following can be
concluded:
1. Compressive strength decreases as the percent of waste crumb tire replacement
increases for various PCC categories.
2. Density decreases as the percent of waste crumb tire replacement increases for various
PCC categories.
3. Water absorption decreases at 25% replacement and pounces back approximately to
its original value at 50% replacement, and then starts to increase as waste crumb tires
increases.
4. Slump test results showed no change in consistency during all mixes; there was no
effect of increasing waste crumb tires replacement on consistency.
5. Abrasion increases as waste crumb tires increases.
6. Modulus of elasticity decreases as waste crumb tires replacement increases.
7. Noise insulation increases as percent of crumb waste tires increases. At low noise
levels, higher insulation of noise occurred than that of high levels of noise.
8. Thermal insulation increases as waste crumb tires percent increases.
5.2 Recommendations
Based on the conclusions drawn above and the laboratory observations, the following are
recommended:
1. Since the addition of crumb tires decreases compressive strength, it is recommended
to use waste crumb tires for non structural Portland cement concrete in buildings such
as floor slabs, floor ribs, under ground slabs, behind building stones and in partitions
etc.
2. It is recommended to use percent of replacements in the vicinity of 25% in the PCC,
since compressive strength still within the acceptable range, also good thermal and
noise insulation can be achieved.
3. It is recommended to use replacements in an increment of 10% for better identification
behavioral changes in the physical characteristics in future research.
4. It is recommended to study the effect of larger sizes of shredded tires on PCC.
5. It is recommended to further test the physical characteristics of PCC through
shrinkage limit, permeability etc.
6. It is recommended to explore the effect of other raw materials in these mixes and
study the changes in physical characteristics.
7. Using waste crumb tires in the production of concrete blocks, ribbed concrete block,
and for paving is strongly recommended.
References
Al-Akhras, N.M., Smadi, M.M., (2002). Properties of tire rubber ash mortar. Proceedings of
the International Conference on Sustainable Concrete Construction, University of
Dundee, Scotland, UK, pp 805–814.
Al-Hadithi A. I., (1999). Using chopped worn-out tires in production of light weight concrete
masonry units. Jordan Second Civil Engineering Conference, 16-17 November 1999,
pp 301-319.
Ali, N.A., Amos, A.D., Roberts, M. (1993). Use of ground rubber tires in Portland cement
concrete. Proceedings of the International Conference on Concrete, University of
Dundee, Scotland, UK, pp 379–390.
Annual Book of ASTM Standards, (1985). Concrete and Mineral Aggregates, volume
04.02.
Benazzouk, A., Queneudec, M. (2002). Durability of cement–rubber composites under freeze
thaw cycles. Proceedings of the International Conference on Sustainable Concrete
Construction, University of Dundee, Scotland, UK, pp 356–362.
Bignozzi, M.C., and Sandrolini, F. (2006). Tire rubber recycling in self compacting concrete.
Cement and Concrete Research 36 (2006) pp 735-739.
Biel, T.D., Lee, H. (1996). Magnesium oxychloride cement concrete with recycled tire rubber.
Transportation Research Record, No. 1561, Transportation Research Board,
Washington, DC, pp 6–12.
Blumenthal M. (1998). What's new with ground rubber? Biocycle, March 1998 V39n3 pp 40
(3).
California Integrated Waste Management Board (CIWMB), and the Department of
Energy Contracting Officer, (1994). Part of a report UCLLNL/DOE – Waste Tires.
DiChristina, M., (1994). Mired in tires. (Junk tires) Popular science, Oct. 1994 v245n4 pp
62(4).
Eldin, N.N., Senouci, A.B. (1993). Rubber-tire particles as concrete aggregates. ASCE
Journal of Materials in Civil Engineering 5 (4), pp 478–496.
Fattuhi, N.I., Clark, N.A. (1996). Cement-based materials containing tire rubber. Journal of
Construction and Building Materials 10 (4), pp 229–236.
Fedro., D., Ahmad, S., Savas, B.Z. (1996). Mechanical properties of concrete with ground
waste tire rubber. Transportation Research Board, Report No. 1532, Transportation
Research Board, Washington, DC, pp 66–72.
Goulias, D.G., Ali, A.H. (1997). Non-destructive evaluation of rubber modified concrete.
Proceedings of a Special Conference, ASCE, New York, pp 111–120.
Heitzman, M. (1992). Design and construction of asphalt paving materials with crumb
rubber. Transportation Research Record No. 1339, Transportation Research Board,
Washington, DC.
Hernandez-Olivares, F., Barluenga, G., Bollati, M., Witoszek, B. (2002). Static and dynamic
behavior of recycled tire rubber-filled concrete. Cement and Concrete Research 32
(10), pp 1587–1596
Hossain, M, Sadeq, M, Funk, L, and Maag, R, (1995). "A study of chunk rubber from recycled
tires as a road construction materials". Proceedings of the 10th Annual Conference
on Hazardous Waste Research, Kansas State University, Manhattan, pp 188-197.
Israeli Central Bureau of Statistics, (2005) Israel.
Khatib, Z.K., Bayomy, F.M. (1999). Rubberized Portland cement concrete. ASCE Journal of
Materials in Civil Engineering 11 (3), pp 206–213.
Khosla, N.P., Trogdon, J.T. (1990). Use of ground rubber in asphalt paving mixtures.
Technical Report, Department of Civil Engineering, North Carolina State University,
Raleigh.
Lee, H.S., Lee, H., Moon, J.S., Jung, H.W. (1998). Development of tire-added latex concrete.
ACI Materials Journal 95 (4), pp 356–364.
Li, G., Stubblefied, M. A., Garrick, G., Eggers, J., Abdie, C., and Haung, B. (2004).
Development of waste tire modified concrete. Concrete and Cement Research 34, pp
309-319.
Li, G., Garrick, G., Eggers, J., Abdie, C., Stubblefied, M. A., and Pang, S. (2004). Waste tire
fiber modified concrete. Composites Part B, 35, pp 305-312.
Naik, T.R, Singh, S.S. (1991). Utilization of discarded tires as construction materials for
transportation facilities. Report No. CBU-1991-02, UWM Center for By-products
Utilization. University of Wisconsin-Milwaukee, Milwaukee, pp 16.
Naik, T.R., Singh, S.S. (1995). Effects of scrap-tire rubber on properties of hot-mix asphaltic
concrete - a laboratory investigation. Report No. CBU 1995-02, UWM Center for Byproducts Utilization, University of Wisconsin-Milwaukee, Milwaukee, pp 93.
Naik, T.R., Singh, S.S., Wendorf, R.B. (1995). Applications of scrap tire rubber in asphaltic
materials: state of the art assessment. Report No. CBU 1995-02, UWM Center for Byproducts Utilization, University of Wisconsin-Milwaukee, Milwaukee, pp 49.
Paine, K.A., Dhir, R.K., Moroney, R., Kopasakis, K. (2002). Use of crumb rubber to achieve
freeze thaw resisting concrete. Proceedings of the International Conference on
Concrete for Extreme Conditions, University of Dundee, Scotland, UK, pp 486–498.
Palestinian Standards (PS-55-2001). Methods of testing concrete, (part 1-5). Palestine
Standards Institute, Palestine.
Papakonstantinou, C. G., and Tobolski, M. J. (2006). Use of waste tire steel beads in Portland
cement concrete. Cement and Concrete
Research.
Paul, J. (1985). Encyclopedia of Polymer Science and Engineering. 14, 787-802.
Pierce, C.E., Blackwell, M.C. (2003). Potential of scrap tire rubber as lightweight aggregate
in flowable fill. Waste Management 23 (3), pp 197–208.
Raghvan, D., Huynh, H., Ferraris, C.F. (1998). Workability, mechanical properties and
chemical stability of a recycled tire rubber-filled cementitious composite. Journal of
Materials Science 33 (7), pp 1745–1752.
Read, J., Dodson, T., Thomas, J. (1991). Experimental project – use of shredded tires for
lightweight fill. Oregon Department of Transportation, Post Construction Report for
Project No. DTFH -71-90-501-OR-11, Salem, OR.
Rostami, H., Lepore, J., Silverstraim, T., Zundi, I. (1993). Use of recycled rubber tires in
concrete. Proceedings of the International Conference on Concrete 2000, University of
Dundee, Scotland, UK, Rubber Manufacturer‫ۥ‬s Association, 2000. Washington, DC pp
391–399.
Rubber
Manufacture's
Association,
(2003).
USA
(Civil
Engineering
Applications).<http://www.epa.gov/epaoswer/nonhw/muncpl/tires/civil_eng.htm>
January 3rd 2007.
Savas, B.Z., Ahmad, S., Fedro., D. (1996). Freeze–thaw durability of concrete with ground
waste tire rubber. Transportation Research Record No. 1574, Transportation
Research Board, Washington, DC, Scrap Tire Management Council, 1998. Scraptires Use, Washington, DC pp 80–88.
Segre, N., Joekes, I. (2000). Use of tire rubber particles as addition to cement paste. Cement
and Concrete Research 30 (9), pp 1421–1425.
Singh, S.S. (1993). Innovative applications of scrap-tires. Wisconsin Professional Engineer,
14–17.
Siddique, R., Naik, T. R. (2004). Properties of concrete containing scrap-tire rubber – an
overview. Waste Management, 24, pp 563-569.
Tantala, M.W., Lepore, J.A., Zandi, I. (1996). Quasi-elastic behavior of rubber included
concrete. Proceedings of the 12th International Conference on Solid Waste
Technology and Management, Philadelphia, PA.
Topcu, I.B. (1995). The properties of rubberized concrete. Cement and Concrete Research
25 (2), pp 304–310.
Topcu, I.B., Avcular, N. (1997a). Analysis of rubberized concrete as a composite material.
Cement and Concrete Research 27 (8), pp 1135–1139
Topcu, I.B., Avcular, N. (1997b). Collision behaviors of rubberized concrete. Cement and
Concrete Research 27 (12), pp 1893–1898.
Tortum, A., Celik, C., and Aydia, A. C. (2005) Determination of the optimum conditions for
tire rubber in asphalt concrete. Building and Environment, 40, pp 1492-1504.
Yoon, S., Prezzi, M., Siddiki, N. Z., Kim, B. (2006). Construction of a test embankment using
a sand-tire shred mixture as fill material. Waste Management, 26, pp 1033-1044.